Pulmonary neutrophil kinetics after thrombin-induced intravascular coagulation

Previous studies have indicated that neutrophils are required for the development of increased lung vascular permeability after thrombin-induced pulmonary microembolization. In this study, we examined neutrophil kinetics and uptake in the sheep lung before and after lung vascular injury. Sheep neutrophils were isolated by a Percoll-gradient method and labeled with indium-111 oxine. A maximum lung activity of 40% of the injected indium-111 neutrophil activity was attained 8-12 min after the injection. The calculated half-lives of both circulating and pulmonary neutrophils were 700 min. The rate of washout of labeled neutrophils from the lungs was the same as the loss of the peripheral blood activity, indicating removal of neutrophils from the lung and blood by a common pathway (e.g., liver and spleen). Intravenous infusion of alpha-thrombin resulted in an immediate uptake of neutrophils of 14% above the base-line activity. The increased uptake was associated with an immediate decrease in the blood activity, indicating sequestration of the neutrophils in the pulmonary circulation. The neutrophil uptake after alpha-thrombin was transient, reaching a maximum 15 min after infusion. Neutrophil uptake did not occur with alpha-thrombin (which lacks the fibrinogen recognition site), suggesting that the uptake was secondary to intravascular coagulation. An increase in the pulmonary blood volume cannot explain the increased neutrophil sequestration because pulmonary blood volume determined by [99mTc]pertechnetate-labeled erythrocytes did not increase after the alpha-thrombin infusion. Therefore, alpha-thrombin results in a transient neutrophil sequestration in the lung, and the response is secondary to the intravascular coagulation induced by the alpha-thrombin.     

Efficient radiolabeling of mammalian cells using 111In-tagged liposomes

When indium-111 oxine labeled neutral liposomes were incubated with Chinese hamster V79 cells in the presence of 100 mM calcium, the cell-associated radioactivity increased approximately 75-fold over that observed in the absence of calcium. This is considerably higher (~20 times) than the cellular uptake obtained when these cells are incubated in the presence of ¹¹¹In-oxine alone. The highest uptake of radioactivity occurred when no bovine serum albumin was present in the medium, while as little as 0.001% of the protein greatly reduced the cell-liposome association. These efficient cell labeling conditions were not found to affect the survival of the cells.     

Sperm-macrophage interaction in the mouse: a quantitative assay in vitro using 111indium oxine-labeled sperm

The role of reproductive tract macrophages in contraception and reproductive failure has become widely recognized. However, in vitro analysis of sperm phagocytosis by macrophages has relied upon a semi-quantitative method of sperm counting that is of limited accuracy and reproducibility. We have developed an assay using murine sperm labeled with 111indium oxine, and results indicate the labeling to be rapid and efficient. Incorporation of 111indium into sperm increased the dose and sperm concentration and reached 90% maximal uptake after 15 min incubation, with maximal uptake occurring at 30 min. No decrease in sperm motility was noted with levels of oxine in excess of those required for significant labeling. Maximal labeling efficiency occurred in phosphate-buffered saline (PBS), with Dulbecco's modified Eagle's medium (DMEM) + 10% adult bovine serum (ABS) producing significantly less uptake. Label dissociation was detectable in PBS at room temperature, but at 37 degrees C in DMEM + 10% ABS, loss of label occurred at a rate of 23.5%/h. Addition of labeled sperm to murine macrophage monolayers under optimal conditions resulted in uptake of 111indium by macrophages, while free label was unincorporated. Results indicated assay specificity for macrophage-limited uptake, with insignificant label uptake by nonphagocytic murine fibroblasts and better sensitivity than sperm counting. Macrophages from Bacillus Calmette-Guerin (BCG)-infected mice resulted in a decrease in sperm uptake. Female macrophages showed greater capacity for sperm uptake than those of the male mouse. These initial studies demonstrated the utility of this model system in enhancing the understanding of sperm-macrophage interaction in the female reproductive tract.     

Radiomarquage in vitro des leucocytes au [F]-fludésoxyglucose : première expérience à l’hôpital d’instruction des armées Val-de-Grâce

^99mTc-HMPAO (technetium^99m-hexamethylpropylene amine oxime) radiolabeled-leukocytes or Indium-111 oxine labeled leukocytes scintigraphy and positron emission tomography with [¹⁸F]-fludeoxyglucose (¹⁸F-FDG) are the reference techniques for infection imaging. These methods have some limits explaining the active research for an ideal infection tracer finding. Because of its potential advantages, leukocyte labeling with ¹⁸F-FDG have been developed but is not routinely used for clinical infection imaging. We report the results of our first experience of leukocyte radiolabeling with ¹⁸F-FDG, managed on 20 healthy subjects. Labeling efficiency, cellular viability and radiolabeling stability have been assessed. Our results exhibit the influence of different parameters on labeling efficiency: presence of glucose during the labeling reaction, number of cells and volumic activity of ¹⁸F-FDG. Stability assessment indicates that 60% of initial cellular activity persist in cells after 1 hour incubation. Our results are similar to literature data and permit us to consider a clinical use of radiolabeled leukocyte with ¹⁸F-FDG. Nevertheless, a clinical use of radiolabeled cells can’t be considered before the radiolabeling induced cellular effects have been assessed.     

Fluorescence probes specific for the plasma membrane of intact human erythrocytes and lymphocytes

Human erythrocytes and lymphocytes were isolated from venous blood and subjected to one of two protocols. In one protocol the suspended cells were labeled with fluorophore (fluorescamine or 12(9)AS). This procedure was followed sequentially by cellular lysis, cellular fractionation, and fluorescence and absorption readings. In the other protocol the suspended cells were lysed, and then the cellular homogenate labeled with fluorophore followed by cellular fractionation and spectroscopy readings. The lymphocytes were fractionated into plasma membrane, cytosol, and nuclear-mitochondrial fractions and the erythrocytes into plasma membrane and cytosol fractions. The results demonstrate that under the given labeling conditions, both fluorescamine and 12(9)AS are highly localized to the plasma membrane of intact human erythrocytes and lymphocytes. Furthermore, by P-31 NMR analysis, fluorophore labeling did not alter cellular high energy phosphate metabolism or cellular permeability to Mn²⁺. Therefore, these fluorophores are potentially powerful probes of human erythrocyte and lymphocyte plasma membrane dynamics in inherited and acquired disease states.     

Optimization of 5-(and-6)-Carboxyfluorescein Diacetate Succinimidyl Ester for Labeling Human Intervertebral Disc Cells in Vitro

We have assessed the utility of an intracellular fluorochrome, 5-(and-6)-carboxyfluorescein diacetate succinimidyl ester (CFSE), as a tracking label for human intervertebral disc cells in vitro. Although 5 JJIM provides adequate intracellular labeling for whole cell fluorescent microscopic identification of labeled cells, 20 JJLM was preferable for immunocytochemical localization of paraffin embedded labeled cells. Electron dense vesicles are seen at the ultra-structural level in labeled cells. Discrete vesicular labeling can also be observed in whole cell mounts viewed with fluorescence microscopy. Whole cells retain good label for 6 weeks. CFSE labeling is relatively easy, nontoxic to cells and nonradiocactive. Initial optimization of dose with specific cells types is recommended when confirmation of positive immunocytochemistry is needed for tissue engineering studies.     

Optimization of 5-(and-6)-Carboxyfluorescein Diacetate Succinimidyl Ester for Labeling Human Intervertebral Disc Cells in Vitro

We have assessed the utility of an intracellular fluorochrome, 5-(and-6)-carboxyfluorescein diacetate succinimidyl ester (CFSE), as a tracking label for human intervertebral disc cells in vitro. Although 5 JJIM provides adequate intracellular labeling for whole cell fluorescent microscopic identification of labeled cells, 20 JJLM was preferable for immunocytochemical localization of paraffin embedded labeled cells. Electron dense vesicles are seen at the ultra-structural level in labeled cells. Discrete vesicular labeling can also be observed in whole cell mounts viewed with fluorescence microscopy. Whole cells retain good label for 6 weeks. CFSE labeling is relatively easy, nontoxic to cells and nonradiocactive. Initial optimization of dose with specific cells types is recommended when confirmation of positive immunocytochemistry is needed for tissue engineering studies.     

Exposure of major neutral glycolipids in red cells to galactose oxidase. Effect of neuraminidase

The exposure of several major red-cell glycolipids to galactose oxidase was studied by oxidizing the cells with the enzyme and reducing them with NaB2H4. After isolation, the deuterium label was detected by mass fragmentography. 60-70% globoside in human and porcine erythrocytes was exposed as measured by this method. In contrast, asialo-GM2 in guinea-pig erythrocytes and Forssman glycolipid in sheep erythrocytes were mainly in a cryptic state. Neuraminidase treatment increased the incorporation of deuterium label to asialo-GM2 4-8-fold. A similar effect was seen in Forssman glycolipid when sheep red cells were labeled with the neuraminidase/galactose oxidase/NaB3H4 method. In contrast, the increase in labeling was only about 10-40% in porcine and human globosides, which were efficiently exposed to galactose oxidase already in native red cells.     

In vivo neutrophil sequestration within lungs of humans is determined by in vitro "filterability".

Neutrophils are normally delayed in transit through the lung microcirculation, relative to the passage of erythrocytes. This sequestration contributes to a pulmonary pool of neutrophils that may relate to the relative inability of neutrophils to deform compared with erythrocytes when in transit in the pulmonary capillaries. A micropore membrane was used to model the human pulmonary microcirculation, in which cell deformability was measured as the pressure developed during filtration of the cells through the membrane at a constant flow. We demonstrated a significant correlation between in vitro deformability and in vivo lung sequestration of indium-111-labeled neutrophils in 10 normal subjects (r = 0.69, P less than 0.02). In eight patients with stable chronic obstructive pulmonary disease, this relationship was not significant (r = -0.2, P greater than 0.05). Furthermore, in a subject with microscopic pulmonary telangiectasia known to allow significant passage of 30-microns microspheres, neutrophils passed through the lungs without delay. Moreover, neutrophils from patients studied acutely with an exacerbation of chronic obstructive pulmonary disease were temporarily less deformable (P less than 0.01). These studies confirm that cell deformability is an important determinant of the normal neutrophil sequestration within the lungs. Changes in cell deformability may alter the extent of this sequestration.     

A dual laser analysis of the migration of XRITC-labeled, FITC-labeled, and double-labeled lymphocytes in sheep

Substituted rhodamine isothiocyanate (XRITC) has been used to study lymphocyte migration in sheep. After being labeled in vitro with XRITC, lymphocytes appeared in the efferent lymph of single lymph nodes with the same kinetics as cells labeled with fluorescein isothiocyanate (FITC). The recovery of intravenously injected XRITC-labeled cells was followed in lymph for several days. The kinetics and recoveries were compared with data obtained using FITC, chromium-51, and indium-111. XRITC was found to be a suitable label and, using dual laser (argon and krypton) flow cytometry, it could be analyzed simultaneously with FITC. In addition, it was possible to relabel FITC-stained cells with XRITC after they were recovered in lymph. The migratory characteristics of such double-labeled cells were not different from single-labeled cells.     

The segregation of DNA in epithelial stem cells

It has recently been suggested that stem cells may invariably keep, from one division to the next, the daughter DNA molecules that contain the older of the two parental strands—that is, they may retain a complete set of “immortal strands,” through successive cell divisions (Cairns, 1975). We can test this hypothesis by labeling either the old immortal strands at the time the stem cells are created or the newly synthesized strands during subsequent divisions of the stem cells. In the former case, the stem cells should become permanently labeled; in the latter case, they should eliminate their label on their second division.Experiments of this sort have been conducted with the tongue papilla under steady state conditions and with the regenerating small intestinal crypts. The results clearly show that by far most of the multiplying cells in tongue and intestinal epithelium segregate their DNA “randomly” at mitosis. Nevertheless, the results, though far from conclusive, suggest that there are a small number of cells (1–5 in the stem cell region of each crypt and one at the base of each column of cells in the tongue) that selectively segregate their old and new DNA strands in the expected way. Thus in the immortal strand labeling experiments, there are a few labeled cells that retain their label for up to 4 weeks; conversely, in the new strand labeling experiments, a few cells appear to rid themselves of label after intervals equivalent to approximately two cell cycles.     

Identification of cyclosporin binding sites in rat liver plasma membranes, isolated hepatocytes, and hepatoma cells by photoaffinity labeling using [3H]cyclosporin-diaziridine

[3H]Cyclosporin diaziridine, a new photoaffinity label, enters rat liver cells in the dark. Photoaffinity labeling of isolated rat liver-cell plasma membranes with this probe modifies several polypeptides with molecular mass of 200, 85, 54, 50, 34 kDa. The major labeled protein of 85 kDa represents 2% of the total plasma membrane protein. A 50 kDa protein is heavily labeled in freshly isolated rat hepatocytes at low temperature and after short incubation in the dark. The 85 kDa protein becomes substituted after longer preincubation periods at temperatures above 10 degrees C. This suggests a localisation at the cytoplasmic side of the membrane. Several controls point to a specific interaction with the above mentioned proteins. Comparison of [3H]cyclosporin-diaziridine- and isothiocyanatobenzamido[3H] cholic acid-labeled membrane proteins reveals identity of binding proteins with the exception of the 85 kDa protein. However, the interaction of bile acids with the 85 kDa protein became apparent at higher concentrations as demonstrated by the differential photoaffinity labeling experiments. In the cytosol of rat liver cells, further [3H]cyclosporin-diaziridine binding proteins could be identified. In particular, a 17 kDa polypeptide was found which appears similar to cyclophilin, a protein known to be present in T-lymphocytes (R. Handschumacher et al. (1984) Science 226, 544-547: Cyclophilin. A specific cytosolic binding protein for cyclosporin A). Proteins with molecular mass of 90, 56, 30, 24, 20 kDa are labeled in AS-30D ascites hepatoma cells and those with molecular mass of 200, 150, 80, 70, 42, 25 kDa in Ehrlich ascites tumor cells.     

Cellular uptake of 3H-actinomycin D in the hematological tissues and liver of the mouse

Actinomycin D(AM), an inhibitor of DNA-dependent RNA synthesis, produces a reversible cessation of red blood cell production. This study examines the in vivo cellular uptake of ³H-AM in the hematological tissues and livers of B6D2F₁ mice. ³H-Am (sp. act. = 2.97 to 4.20 C/mmole) was given IV at a dose of 4.0 to 5.7 μg (14 μc) per mouse. Spleen, bone marrow, blood, and liver samples were taken for autoradiography at post-injection times of five minutes to 67 hours. We have confirmed the rapid in vivo cellular uptake of AM; substantial quantities of the drug were in the nuclei within five minutes of IV administration. Not all cell types became labeled. Erythroid, hepatic, lymphoid, and reticulo-endothelial (RE) cells and monocytes took up the label, whereas labeling of granulocytic elements was doubtful. Most heavily labeled were liver cells (highest mean grain count = 110.1) and splenic RE(19.1) and erythroid (16.1) cells. Erythroid cells in the spleen were more heavily and more rapidly labeled than those in the bone marrow. All nucleated erythroid maturational stages, in both the spleen and the bone marrow, were labeled, even at five minutes. The time course of erythroid and hepatic labeling was quite different. Whereas early erythroid cells required six hours to become 100% labeled, liver cells were 100% labeled at five minutes and loss of hepatic labeling began as early as 15 to 30 minutes.     

Species-specific phosphorylation of mouse and rat p53 in simian virus 40-transformed cells.

We have analyzed in detail the phosphorylation of p53 from normal (3T3) and simian virus 40 (SV40)-transformed (SV3T3) BALB/c mouse cells and from normal (F111) and SV40-transformed [FR(wt648)] rat cells by two-dimensional tryptic peptide mapping and phosphoamino acid analyses. To accommodate the different half-lives of p53 in normal (half-life, 15 min) and transformed (half-life, 20 h) cells and possible differences in the rates of turnover of phosphate at specific sites, cells were labeled for 2 h (short-term labeling) or 18 h (long-term labeling). Depending on the labeling conditions, either close similarities or marked differences were observed in the phosphorylation patterns of p53 from normal and transformed cells. After the 2-h labeling, the phosphorylation patterns of p53 from normal and transformed mouse cells were quite similar. In contrast, p53 from normal and transformed rat cells exhibited dramatic quantitative and qualitative differences under these labeling conditions. The reverse was found after an 18-h label leading to steady-state phosphorylation of p53 in transformed cells: while p53 in transformed mouse cells revealed a marked quantitative increase in phosphorylation compared with p53 from normal cells, the corresponding patterns of p53 from normal and transformed rat cells were similar. Our data thus indicate species-specific differences in the phosphorylation of mouse and rat p53 in SV40-transformed cells, reflected by (i) different turnover rates at specific sites in mouse and rat p53 and (ii) phosphorylation of nonhomologous serine and threonine residues in rat p53, as revealed by indirect assignment of phosphorylation sites to the phosphopeptides of rat p53. Analyses of p53 from the SV40 tsA58 mutant-transformed F111 cell lines FR(tsA58)A (N type) and FR(tsA58)57 (A type) yielded no conclusive evidence for a direct correlation between phosphorylation of p53, the metabolic stabilization of p53, and expression of the transformed phenotype.     

Localization of thyroglobulin antigenicity in rat thyroid sections using antibodies labled with peroxidase or (125)I-radioiodine

In the hope of localizing thyroglobulin within focullar cells of the thyroid gland, antibodies raised against rat thyroglobulin were labeled with the enzyme horseradish peroxidase or with (125)I-radioiodine. Sections of rat thyroids fixed in glutaraldehyde and embedded in glycol methacrylate or Araldite were placed in contact with the labeled antibodies. The sites of antibody binding were detected by diaminobenzidine staining in the case of peroxidase labeling, and radioautography in the case of 125(I) labeling. Peroxidase labeling revealed that the antibodies were bound by the luminal colloid of the thyroid follicles and, within focullar cells, by colloid droplets, condensing vacuoles, and apical vesicles. (125)I labeling confirmed these findings, and revealed some binding of antibodies within Golgi saccules and rough endoplasmic reticulum. This method provides a visually less distinct distribution than peroxidase labeling, but it allowed ready quantitation of the reactions by counts of silver grains in the radioautographs. The counts revealed that the concentration of label was similar in the luminal colloid of different follicles, but that it varied within the compartments of follicular cells. A moderate concentration was detected in rough endoplasmic reticulum and Golgi saccules, whereas a high concentration was found in condensing vacuoles, apical vesicles, and in the luminal colloid. Varying amounts of label were observed over the different types of colloid droplets, and this was attributed to various degrees of lysosomal degradation of thyroglobulin. It is concluded that the concentration of thyroglobulin antigenicity increases during transport from the ribosomal site of synthesis to the follicular colloid, and then decreases during the digestion of colloid droplets which leads to the release of the thyoid hormone.     

New 111In labeling of IgG: 111In-oxine mediated chelation

Current methods of ¹¹¹In chelate conjugation labeling of antibodies expose the protein to pH 5–6 during ¹¹¹In chelation. These conditions could be detrimental if the antibody is acid labile. We have successfully labeled human IgG via the cyclic anhydride of DPTA and ¹¹¹In-oxyquinoline(oxine). Chelation was achieved at pH 6.9–8.4 and was complete within 1 min at room temperature. The chelation was sensitive to trace metal contamination on labware and in some reagents (including commercial ¹¹¹In-oxine).     

Long-term tracking of lymphocytes in vivo: the migration of PKH-labeled lymphocytes

Studies of in vivo cell migration using cell markers such as 51Cr, 111In, FITC, or XRITC have been limited to short time periods due to the elution, toxicity, or rapid loss of label detectability. We have labeled sheep lymphocytes in vitro with PKH-2, a new fluorescent cell membrane label, and, after their intravenous injection back into donor sheep, have been able to detect them in efferent lymph, using flow cytometry, for longer than 38 days. The PKH-2-labeled lymphocytes migrated with similar kinetics, efficiency, and tissue specificity as lymphocytes labeled with cell markers used previously. PKH-2-labeled cells mediated graft versus host reactions indistinguishable from those mediated by unlabeled cells, and cell surface antigens were equally detectable on the surface of labeled and unlabeled lymphocytes. According to the slow, consistent loss of fluorescence intensity of the labeled cells in vivo, we predict that labeled lymphocytes could remain detectable by flow cytometry for greater than 7 weeks with the labeling protocol used in these experiments.     

Surface-specific iodination of membrane proteins of viruses and eucaryotic cells using 1,3,4,6-tetrachloro-3alpha,6alpha-diphenylglycoluril.

The use of the iodinating reagent 1,3,4,6-tetrachloro-3alpha,6alpha-diphenylglycouril (chloroglycoluril) to selectively label membrane surface proteins was investigated with the following systems: enveloped viruses (Sendai and Newcastle disease viruses), human erythrocytes, and nucleated cells propagated both in suspension (EL-4) and in monolayer culture (BHK-21). Conditions are described for specifically iodinating surface proteins while maintaining full virus integrity or cell viability. Comparison of the chloroglycoluril method with the lactoperoxidase and chloramine-T methods for labeling surface membrane proteins shows that the chloroglycoluril method has a number of advantages: It routinely produces a 3- to 17-fold greater specific radioactivity without sacrificing viral or cellular integrity, it is technically simpler to use, it does not require the addition of extraneous protein to initiate the reaction nor a strong reducing reagent to terminate it. Chloroglycoluril also proved to be an effective substitute for chloramine-T in the nonvectorial labeling of viral and cellular proteins. Membrane protein samples were solubilized with the detergent sodium dodecyl sulfate before iodination or labeled in the presence of high iodide concentrations without prior solubilization. The resulting specific radioactivities generated by the use of chloroglycoluril were equal to or greater than those generated by the chloramine-T method. The effectiveness, simplicity of use, and versatility of chloroglycoluril recommend it as an iodinating reagent for both surface-specific and nonvectorial labeling of membrane systems.     

Labeling of hepatic glycogen after short- and long-term stimulation of glycogen synthesis in rats injected with 3H-galactose

The effects of short- and long-term stimulation of glycogen synthesis elicited by dexamethasone were studied by light (LM) and electron (EM) microscopic radioautography (RAG) and biochemical analysis. Adrenalectomized rats were fasted overnight and pretreated for short- (3 hr) or long-term (14 hr) periods with dexamethasone prior to intravenous injection of tracer doses of 3H-galactose. Analysis of LM-RAGs from short-term rats revealed that about equal percentages (44%) of hepatocytes became heavily or lightly labeled 1 hr after labeling. The percentage of heavily labeled cells increased slightly 6 hr after labeling, and unlabeled glycogen became apparent in some hepatocytes. The percentage of heavily labeled cells had decreased somewhat 12 hr after labeling, and more unlabeled glycogen was evident. In the long-term rats 1 hr after labeling, a higher percentage of heavily labeled cells (76%) was observed compared to short-term rats, and most glycogen was labeled. In spite of the high amount of labeling seen initially, the percentage of heavily labeled hepatocytes had decreased considerably to 55% by 12 hr after injection; and sparsely labeled and unlabeled glycogen was prevalent. The EM-RAGs of both short- and long-term rats were similar. Silver grains were associated with glycogen patches 1 hr after labeling; 12 hr after labeling, the glycogen patches had enlarged; and label, where present, was dispersed over the enlarged glycogen clumps. Analysis of DPM/mg tissue corroborated the observed decrease in label 12 hr after administration in the long-term animals. The loss of label observed 12 hr after injection in the long-term pretreated rats suggests that turnover of glycogen occurred during this interval despite the net accumulation of glycogen that was visible morphologically and evident from biochemical measurement.